KR20150027115A - Graphene powder, method for producing graphene powder and electrode for lithium ion battery containing graphene powder - Google Patents

Abstract

There is provided a graphene powder and a method for producing the same, in order to produce a high conductivity and highly dispersible graphene powder and to obtain an electrode for a lithium ion battery having excellent performance using graphene with high conductivity and high dispersibility. The graphene powder comprises a compound having a catechol group adsorbed on the surface of graphene at a weight ratio of 5-50% to graphene, and is characterized in that the graphene powder has a ratio of oxygen to carbon in the graphene powder measured by X-ray photoelectron spectroscopy Is 0.06 or more and 0.20 or less. The process for producing graphene powder includes reducing graphite oxide using a reducing agent having no catechol group in the presence of a compound having a catechol group.

Description

TECHNICAL FIELD [0001] The present invention relates to a graphene powder, a method for producing the graphene powder, and an electrode for a lithium ion battery containing the graphene powder. BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a graphene powder,

The present invention relates to a highly dispersible and highly conductive graphene powder and a process for its preparation.

Graphene is a two-dimensional crystal consisting of carbon atoms and a source material that has attracted considerable attention since its discovery in 2004. Graphene has excellent electrical, thermal, optical and mechanical properties and is believed to be applied to a wide range of fields, such as battery materials, materials for energy storage, electronic devices and composite materials.

In order to implement this application of graphene, it is necessary to make an efficient manufacturing method to reduce the cost and to improve the dispersibility.

Examples of the manufacturing method of graphene include a mechanical peeling method, a CVD (chemical vapor deposition) method, a CEG (crystal epitaxial growth) method, and the like, and these methods have low productivity and are not suitable for manufacturing materials. On the other hand, the oxidation-reduction method (a method of oxidizing natural graphite to obtain graphite oxide or graphene oxide and subsequently producing graphene by reduction reaction) can reach a large scale synthesis of graphene, This is a very important way to actually use.

Examples of conventional techniques of the oxidation-reduction method include a high temperature thermal reduction method and a reduction method with hydrazine. In Patent Document 1, for example, graphene is produced by thermally reducing graphite oxide at an elevated temperature of 1050 DEG C, but the method is carried out at a high temperature in connection with the conditions, and thus costly facilities are required. Ruoff et al. Used hydrazine hydrate as a reducing agent and reduced graphene oxide by water reaction at 100 ° C for 24 hours (Non-Patent Document 1). However, hydrazine reducing agents are highly toxic and difficult to use industrially.

In addition, since graphene is a nanocarbon and it is very difficult to disperse because of its high specific surface area, improvement in dispersibility is a very important task for the application of graphene. (Li) et al. Reported that graphene was electrostatically charged by adding aqueous ammonia while reducing graphite oxide using hydrazine hydrate as a reducing agent, thereby obtaining graphene stably dispersed in water (Non-Patent Document 2) In this way, the solvent is limited to water.

In Patent Document 2, a relatively stable graphene dispersion was prepared from graphite oxide using phenolamine as a reducing agent. Since the graphite oxide could not be sufficiently reduced with phenolamine, sufficient conductivity could not be reached. Liu et al. And Kaminska et al. Each reduced graphite oxides using dopamine as a reducing agent (non-patent document 3) and azide of dopamine (non-patent document 4), but the graphite oxide was sufficiently reduced , Graphene with high conductivity could not be reached.

Patent Document 1: U.S. Patent No. 7658901 Patent Document 2: Chinese Patent Publication CN102398900A

Non-Patent Document 1: Lou Off et al. [Carbon, 2007, 45, 1558] Non-Patent Document 2: Li et al. [Nature Nanotechnology, 2008, 3, 101] Non-Patent Document 3: Ryu et al. [J. Phys. Chem. C, 2012, 116, 3334-3341] Non-Patent Document 4: Kaminska et al. [Appl. Mater. Interface, 2012, 4, 1016]

In this way, graphene having high dispersibility in an organic solvent has not been obtained so far while maintaining high conductivity. For this reason, there has been no disclosure as to an example of successfully using graphene as a conductive additive for a lithium ion battery electrode up to now.

A first object of the present invention is to produce high conductivity and high dispersibility graphenes and a second object is to provide an electrode for a lithium ion battery having good output characteristics and cycle characteristics by using high conductivity and high dispersibility graphenes ≪ / RTI >

The present inventors have found that by adhering a certain amount of a compound having a catechol group to graphene, grains of high conductivity and high dispersibility can be obtained.

That is, the present invention relates to a graphene powder in which a compound having a catechol group is adhered to a graphene surface at a weight ratio of not less than 5% and not more than 50% of graphene, and graphene powder measured by X-ray photoelectron spectroscopy The elemental consumption of oxygen to carbon in the powder is not less than 0.06 and not more than 0.20.

The graphene powder according to the present invention can be imparted with dispersibility in an organic solvent while maintaining a high conductivity since a compound having a catechol group is appropriately adhered to the surface of graphene. It is also possible to provide an electrode for a lithium ion battery having excellent discharge performance by using such a high dispersing and high conductivity graphene together with a binder and an electrode active material.

Fig. 1 shows a comparison of X-ray diffraction spectra of graphite oxide prepared in Example 1 according to the present invention and graphite oxide prepared in Synthesis Example 1 and natural graphite as a coarse material. As shown in the figure, there are few diffraction peaks in graphene derived from graphite, compared to the sharp diffraction peaks of natural graphite and graphite oxide, suggesting that sufficiently thin graphene was produced.

<Grain powder>

The graphene powder refers to a powder containing graphene, and the graphene powder according to the present invention is a compound having a catechol group adhered to the graphene surface.

[GRAPHIN]

Graphene has a structure consisting of a single-layer graphene sheet stacked together and has a flaky morphology. There is no particular limitation on the thickness of graphene, but it is preferably 100 nm or less, more preferably 50 nm or less, further preferably 20 nm or less. There is no particular limitation on the size of the graphene in the horizontal direction, and the lower limit is preferably 0.5 μm or more, more preferably 0.7 μm or more, further preferably 1 μm or more, and the upper limit is preferably 50 μm More preferably not more than 10 mu m, further preferably not more than 5 mu m. In this regard, the horizontal size of the graphene refers to the average of the longest length of the major axis of the graphene plane and the minimum length of the minor axis.

[Compound having a catechol group]

In the graphene powder according to the present invention, the compound having a catechol group is adhered to the surface. Since the compound having a catechol group has an aromatic ring, it tends to adhere to the graphene surface due to the pi-pi lamination interaction. Further, since the catechol group has a plurality of phenol hydroxyl groups, it has a great effect in enhancing the dispersibility. Therefore, graphene in which a compound having a catechol group is adhered to a surface has a very high level of dispersion stability. In fact, the tackiness or adherence or absorbency of the catecholate was found from marine organisms called mussels. Because the catechol is present in the adhesive proteins of the mussels, the mussels have a magical adhesion that can attach to many kinds of surfaces. Compounds containing catechol groups can mimic the magical adhesion of mussels and can attach to the surface of graphene.

Specifically, such a compound having a so-called catechol group refers to a compound having a structure in which a part or all of the 3-position to 6-position of 1,2-benzenediol is modified. The category itself is also included.

In connection with the above-mentioned compounds having a catechol group, it is possible to use catechol, dopamine hydrochloride, dopa, noradrenaline, 3,4-dihydroxybenzoic acid, 3,4-dihydroxyphenylacetic acid, And 4-tert-butyl pyrocatechol are preferable. Above all, catechol, dopamine hydrochloride, and dopa are more preferable. Among them, dopamine hydrochloride and dopa are particularly preferable.

In the present invention, the step of adhering a compound having a catechol group to the surface of graphene is carried out by performing a step of adhering a compound having a catechol group to the surface and performing filtration to obtain a graphene powder, And then drying the solution by a freeze-drying method, a spray-drying method or the like, and allowing the compound having a catechol group to remain in the graphene powder Quot;

In the present invention, the weight ratio of the compound having a catechol group attached to graphene is 5% or more and 50% or less. When the proportion of the compound having a catechol group on the surface is too low, it is impossible to impart sufficient dispersibility to the graphene powder. On the other hand, when the proportion of the compound having a catechol group is too high, the conductivity of the graphene powder becomes low. The weight ratio of the compound having a catechol group in the graphene powder is preferably 10% or more, more preferably 15% or more. It is also preferably not more than 30%, further preferably not more than 25%.

The method of adhering the compound having a catechol group on the surface is not particularly limited. The compound having a catechol group can be mixed with graphene, and the graphite oxide can be reduced in the presence of a compound having a catechol group.

There is no particular limitation on the mixing method of the compound having a catechol group and graphene, and known mixers and kneaders can be used. Specifically, examples thereof include a method using magnetic-working mortar, triple roll mill, bead mill, planetary ball mill, homogenizer, planetary mixer, biaxial kneader and the like. Of these, planetary ball mills are suitable for mixing two different powders.

The method of quantifying a compound having a catechol group contained in graphene powder varies depending on the kind of compound having a catechol group. When the compound having a catechol group contains a nitrogen atom or a sulfur atom, it can be quantitatively determined from the ratio of the nitrogen atom or the sulfur atom to the carbon atom measured by X-ray photoelectron spectroscopy or the like. When a compound having a catechol group does not have a nitrogen atom or a sulfur atom, a compound having a catechol group is quantitatively analyzed by an analytical method such as thermal desorption GC-MS and TPD-MS, Lt; RTI ID = 0.0 &gt; finned &lt; / RTI &gt; powder to the total weight of the finned powder.

In particular, when the compound having a catechol group sticking to the surface is dopamine hydrochloride or dopa, it is preferable to analyze nitrogen atoms by X-ray photoelectron spectroscopy. In this case, the ratio of nitrogen atoms to carbon atoms in the graphene powder measured by X-ray photoelectron spectroscopy is preferably not less than 0.005 and not more than 0.02, further preferably not less than 0.01 and not more than 0.015.

[Oxygen / carbon one consumption]

Oxygen atoms in graphene powder are derived from two sources. One is from a functional group possessed by graphene itself, for example, an oxygen atom contained in a hydroxyl group, a carboxyl group and a carbonyl group. And the other is derived from an oxygen atom contained in a compound having a catechol group adhered to the surface of graphene.

In the present invention, the original consumption of oxygen to carbon in the graphene powder should be 0.06 or more and 0.2 or less. Also, it is preferably not less than 0.08 and not more than 0.15, further preferably not less than 0.09 and not more than 0.13. When the amount of oxygen atoms in the graphene powder is too small, the dispersibility of the graphene powder deteriorates. When the amount of oxygen atoms in the graphene powder is too large, the graphene is not sufficiently reduced and the conductivity is low.

The elemental consumption of oxygen to carbon in graphene powder can be quantitatively determined by X-ray photoelectron spectroscopy. In X-ray photoelectron spectroscopy, soft X-rays are irradiated to the surface of a sample placed in a very high vacuum and photoelectrons emitted from the surface are detected by an analyzer. A wide range of scans are performed to measure such photoelectrons and information on the elements in the material is obtained by measuring the value of the binding energy of the bound electrons in the material. In addition, it is possible to quantitatively measure the raw consumption by using the peak area ratio.

&Lt; Production method of graphene powder >

The graphene powder according to the present invention can be produced by a manufacturing method comprising, for example, reducing graphite oxide with a reducing agent different from a compound having a catechol group in the presence of a compound having a catechol group.

[Graphite oxide]

In the present invention, the graphite oxide refers to a material obtained by oxidizing graphite, and has a peak at 9-13.0 DEG which is a peak specific to graphite oxide in the X-ray diffraction measurement. With respect to this graphite oxide, the structure collapses according to conditions such as the pH in the solution, and a 1- to few-layer graphene sheet is formed depending on the degree of oxidation.

There is no particular limitation on the method for producing the graphite oxide, and conventional methods such as the method of Hummers can be used. In addition, ordinary graphite oxides can be obtained. As a method for producing graphite oxide used for the present invention, the case of using Humus's method will be exemplified below.

Graphite as a crude material of graphite oxide may be artificial graphite or natural graphite, but natural graphite is preferably used. The number of meshes for the coarse graphite is preferably 300 to 20000, further preferably 500 to 5000.

Graphite (graphite powder) and sodium nitrate are added to the concentrated sulfuric acid. During stirring, potassium permanganate is gradually added to prevent the temperature from increasing. The mixture is allowed to undergo the reaction with agitation at 25 to 50 DEG C for 0.2 to 5 hours. Thereafter, the reaction mixture is added and diluted with ion-exchanged water to prepare a suspension, and the suspension is subjected to the reaction at 80 to 100 DEG C for 5 to 50 minutes. Finally, hydrogen peroxide and deionized water are added and the reaction is allowed to take place for 1 to 30 minutes to obtain a graphite oxide suspension. The resulting graphite oxide suspension is filtered and washed to obtain a graphite oxide gel. The solvent may be removed from the graphite oxide gel by a freeze-drying method, a spray-drying method, or the like to obtain a graphite oxide powder.

The given description for each reactant is, for example, for 10 g of graphite, 150 to 300 ml of concentrated sulfuric acid, 2 to 8 g of sodium nitrate, 10 to 40 g of potassium permanganate and 40 to 80 g of hydrogen peroxide. When sodium nitrate and potassium permanganate are added, the temperature is adjusted using an ice bath. When hydrogen peroxide and deionized water are added, the mass of deionized water is 10 to 20 times the mass of hydrogen peroxide. It is preferable to use concentrated sulfuric acid having a mass concentration of 70% or more, and more preferably, concentrated sulfuric acid having a mass concentration of 97% or more.

Graphite oxide has high dispersibility but can not be used as a conductive additive or the like because it is an insulator itself. When the degree of oxidation of the graphite oxide is too high, the conductivity of the graphene powder obtained by reduction may deteriorate. As described above, the ratio of oxygen atoms to carbon atoms in the graphite oxide is preferably 0.5 or less. Further, when the inner portion of the graphite is not oxidized well, it becomes difficult to obtain the flaky graphene powder when the graphite oxide is reduced. Accordingly, when the graphite oxide is subjected to X-ray diffraction measurement, it is preferable that no peak specific to graphite is detected.

Reduction of graphite oxide in the presence of a compound having a catechol group [

In order to reduce the graphite oxide in the presence of the compound having the catechol group, the compound having the catechol group and the graphite oxide need to be mixed appropriately. For example, a compound having a graphite oxide and a catechol group may be dispersed in a solvent. In this case, it is preferred that both the graphite oxide and the compound having the catechol group are completely dissolved, but a part thereof remains unmelted and may remain in the solid. As the solvent, a polar solvent is preferable, and examples thereof include, but not limited to, water, ethanol, methanol, 1-propanol, 2-propanol, N-methylpyrrolidone, dimethylformamide, dimethylacetamide, ,? -butyrolactone, and the like. In order to reduce it in the presence of a compound having a catechol group, a solvent is not always necessary as long as the compound having a graphite oxide and a catechol group is appropriately mixed. Those in the solid state can be mixed by kneading.

The graphite oxide is reduced in the presence of a compound having a catechol group to a reducing agent having no catechol group (hereinafter abbreviated as a reducing agent). Since the catechol group has an aromatic ring, it tends to adsorb on the graphite oxide surface. Therefore, when the graphite oxide is reduced by a compound having a catechol group, the oxide is adsorbed and remains excessively on the surface and deteriorates the conductivity. As the reducing agent, a substance which is less prone to adsorb on the graphite oxide surface is preferable, and a material having no aromatic ring is preferable. From the viewpoint that the oxide tends to remain after the reduction, an inorganic reducing agent is preferable as the reducing agent in the present invention. Examples of the inorganic reducing agent to be used include sodium aditionate, potassium aditionate, phosphorous acid, sodium borohydride, hydrazine and the like. Of these, sodium aditionate and potassium aditionate which are capable of easily reducing the graphite oxide at room temperature are particularly preferable.

The amount of the reducing agent is not particularly limited, but an amount capable of sufficiently reducing the graphite oxide is preferable, and a mass ratio of the reducing agent to the graphite oxide is preferably 1: 1 to 3: 1.

There is no particular limitation on the concentration of the graphite oxide in the graphite oxide dispersion for the reduction reaction, but it is preferably 0.1 to 100 mg / ml. After the reduction reaction, filtration and washing with water, the solvent is removed by freeze-drying, spray-drying or the like to obtain a graphene powder.

During the reduction process, the weight ratio of the compound having a catechol group to the graphite oxide in the mixture is not particularly limited. It is preferably not less than 0.2 and not more than 4, further preferably not less than 0.5 and not more than 2, since it affects the amount of the compound having a catechol group remaining on the surface of graphene.

As described above, graphene produced by reducing graphite oxide with a reducing agent having no catechol group in the presence of a compound having a catechol group has a high dispersibility, which makes it possible to be particularly suitably dispersed in a polar solvent. Suitable solvents for the dispersion include N-methylpyrrolidone,? -Butyrolactone, dimethylformamide, dimethylacetamide, carboxymethylcellulose and the like. Having a high dispersibility in these solvents enables it to be suitably used as a material for batteries.

<Electrode for lithium ion battery>

Conductive additives are typically contained in the electrodes for lithium ion batteries. The conductive additive can be made only of the graphene powder according to the present invention, and further other materials can be added. Other conductive additives to be added include, but are not limited to, carbon black such as furnace black, ketjen black and acetylene black, graphite such as natural graphite (such as graphite graphite) and artificial graphite, conductive fibers such as carbon fibers, Metal fibers, metal powders such as copper, nickel, aluminum and silver powder, and the like.

The electrode active material is roughly classified into a cathode active material and a cathode active material, but the present invention can be applied to all of these cases.

Examples of the positive electrode active material include, but not limited to, complex oxides of lithium and a transition metal such as lithium cobalt (LiCoO ₂ ), lithium nickel (LiNiO ₂ ), spinel lithium manganese (LiMn ₂ O ₄ ) or a ternary system material (LiMn _x Ni _y Co _1-xy O ₂ ) in which a part of cobalt is substituted with nickel and manganese, an olivine based (phosphate based) active material such as lithium iron phosphate (LiFePO ₄ ) (LiMnPO ₄ ), metal oxides such as V ₂ O ₅ , metallic compounds such as TiS ₂ , MoS ₂ and NbSe ₂ , and the like.

Examples of the negative electrode active material include, but are not limited to, carbon-based materials such as natural graphite, artificial graphite and hard carbon, SiO 2, SiC, SiOC, etc., Metal oxides such as manganese oxide (MnO) and cobalt oxide (CoO), and the like.

The binder may be selected from fluorine-based polymers such as polyvinylidene fluoride (PVDF) and polytetrafluoroethylene (PTFE) and rubbers such as styrene-butadiene rubber (SBR) and natural rubbers.

An electrode for a lithium ion battery can be manufactured by mixing an active material, a binder, and a conductive additive with a suitable amount of a solvent to prepare an electrode paste, applying the electrode paste to a current collector, and drying the electrode paste. Examples of the electrode paste solvent include N-methylpyrrolidone,? -Butyrolactone, carboxymethylcellulose, dimethylacetamide and the like, and N-methylpyrrolidone is particularly frequently used.

The graphene powder according to the present invention has a good dispersibility in the electrode paste solvent because the compound having a catechol group sticks to the surface. Therefore, with respect to the electrode for a lithium ion battery according to the present invention, it is possible to provide an electrode for a lithium ion battery which improves the electrical conductivity at the electrode and has excellent performance, by allowing the graphene powder to be well dispersed in the electrode .

Example

[Chemicals used in the present invention]

Natural graphite powder: purchased from Shanghai Yi Fan Shi Mo Co., Ltd.

Sodium dithionite, sodium aditionate, hydrazine hydrate, N-methylpyrrolidone, and the like are commercially available from China National Pharmaceutical Group Corporation) or a reagent company belonging to Aladdin Reagents Co., Ltd.

[Measurement example 1: Measurement of powder resistance]

By forming the sample into a disk-shaped specimen having a diameter of about 20 mm and a density of 1 g / cm ³ , the electrical conductivity of the sample can be measured with a high resistivity meter MCP-HT450, available from Mitsubishi Chemical Corporation, The measurement was made using a measuring instrument MCP-T610.

[Measurement example 2: X-ray photoelectron measurement]

X-ray photoelectron measurements were performed on each sample using a Quantera SXM (available from ULVAC-PHI, Inc.). The X- ray herein was a solid _{Al Κα 1,2 (1486.6 eV),} X- wire diameter was 200 μm, photoelectron take-off angle was the angle of 45 degrees.

[Measurement example 3: performance evaluation of dispersibility]

The performance of the dispersibility was measured in the following manner. 1 part by weight of graphene powder and 99 parts by weight of N-methylpyrrolidone prepared in the following examples were placed in a sample bottle, and the bottle was ultrasonicated for 30 minutes by using an ultrasonic washing machine, after which the contents were settled, The condition was visually observed. When the solution was visually uniform, it was judged to be in a state of good dispersibility. When the top of the solution became clear or a precipitate was observed at the bottom of the solution, it was judged to be in a layered state.

[Measurement example 4: Evaluation of battery performance]

The discharge capacity was measured by the following method. Using a planetary mixer, 1 part by weight of graphene powder prepared in the following example, 90 parts by weight of lithium iron phosphate as an electrode active material, 4 parts by weight of acetylene black as a conductive additive, 5 parts by weight of polyvinylidene fluoride And 100 parts by weight of N-methylpyrrolidone as a solvent were mixed to obtain an electrode paste. Electrode paste was applied to a sheet (18 μm thick) of aluminum foil using a doctor blade (300 μm) and dried at 200 ° C. for 15 minutes to obtain an electrode plate.

The prepared electrode plate was cut into pieces having a diameter of 15.9 mm to produce an anode, and the sheet of lithium foil was cut into pieces having a diameter of 16.1 mm and a thickness of 0.2 mm to produce a cathode, and a cell guard (Celgard) A sheet of # 2400 (available from Celgard KK) was cut into pieces having a diameter of 17 mm to produce a separator, and 1M LiPF ₆ -containing solvent of ethylene carbonate: diethyl carbonate = 7: 3 Electrolytic evaluation was performed by using 2042 type coin cell as electrolyte solution. The charge and discharge measurements were performed three times at a rate of 1 C, an upper limit voltage of 4.0 V and a lower limit voltage of 2.5 V, and the capacity in the third discharge was defined as the discharge capacity.

[Synthesis Example 1]

Production method of graphite oxide: 1,500-mesh natural graphite powder (Shanghai Dynix Co., Ltd.) was used as crude material. 330 ml of 98% concentrated sulfuric acid, 5.25 g of sodium nitrate and 31.5 g of potassium permanganate were added to 15 g of natural graphite powder in an ice bath, and the mixture was mechanically stirred for 1.5 hours. The temperature of the liquid mixture was kept below 20 &lt; 0 &gt; C. Liquid mixture was removed from the ice bath and the reaction was allowed to undergo a reaction at 35 占 폚 in a water bath for 2.5 hours with stirring and then the suspension obtained by adding 690 ml of ion-exchanged water to the mixture was reacted at 90 占 폚 for an additional 15 minutes I have suffered. Finally, 1020 ml of ion-exchanged water and 50 ml of hydrogen peroxide were added to the reaction mixture and the reaction was carried out for 5 minutes to obtain a graphite oxide dispersion. The dispersion at high temperature was filtered, the metal ions contained therein were washed with dilute hydrochloric acid solution, the acid contained therein was washed with ion exchange water, and the washing was repeated until pH 7 was reached to prepare graphite oxide gel. The elemental composition ratio of oxygen atoms to carbon atoms in the graphite oxide was measured to be 0.45.

[Example 1]

(1) Production method of graphite oxide dispersion: The graphite oxide gel prepared in Synthesis Example 1 was diluted with deionized water to a concentration of 5 mg / ml, and subjected to ultrasonic treatment. Thereafter, a uniformly dispersed ocher- .

(2) Preparation of graphene powder: To 200 ml of a dispersion of graphite oxide, 0.5 g of dopamine hydrochloride was added as a dispersant, and 3 g of sodium aditionate was added as a reducing agent. The reduction reaction temperature was reduced with a mechanical stirrer at 40 ° C for 30 minutes as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of graphene powder after reduction was 2.33 x 10 ³ S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2, and the result showed that the elemental consumption of oxygen to carbon was 0.11 and the elemental consumption of nitrogen to carbon was 0.013. Assuming that all of the nitrogen was derived from dopamine hydrochloride, the weight ratio of dopamine hydrochloride to graphene was calculated to be 18%.

The performance of the dispersion of graphene powder was measured according to Example 3, and as a result it was evenly dispersed even after 30 days and no sedimentation was observed.

An electrode for a lithium ion battery containing graphene powder was prepared according to Example 4 and the discharge capacity was measured, which was measured as 152 mAh / g.

The results are collected in Table 1.

[Example 2]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Preparation of graphene powder: 0.5 g of catechol as a dispersant was added to 200 ml of a dispersion of graphite oxide, and 3 g of sodium aditionate was added as a reducing agent. The reduction reaction temperature was reduced with a mechanical stirrer at 40 ° C for 30 minutes as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was measured to 8.70 x 10 ^-4 S / m and the electrical conductivity of the graphene powder after reduction was measured to be 1.52 x 10 ³ S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measurement, and as a result the elemental consumption of oxygen to carbon was 0.11. After reduction, the graphene powder was measured by thermal desorption GC-MS, and as a result, the weight ratio of catechol in the graphene powder was 16%.

The performance of the dispersion of graphene powder was measured according to Example 3, and as a result it was evenly dispersed even after 30 days and no sedimentation was observed.

An electrode for a lithium ion cell containing graphene powder was prepared according to Example 4 for measurement and the discharge capacity was measured, which was measured to be 150 mAh / g.

The results are collected in Table 1.

[Example 3]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Production method of graphene powder: 0.5 g of waveguide was added as a dispersant to 200 ml of a dispersion of graphite oxide, and 3 g of sodium aditionate was added as a reducing agent. The reduction reaction temperature was reduced with a mechanical stirrer at 40 ° C for 30 minutes as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of the graphene powder after reduction was 4.35 x 10 ³ S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measurement. As a result, the elemental consumption of oxygen to carbon was 0.11 and the elemental consumption of nitrogen to carbon was 0.012. By assuming that all nitrogen was derived from the waveguide, the weight ratio of waveguide to graphene was calculated to be 17%.

The performance of the dispersion of graphene powder was measured according to Example 3, and as a result it was evenly dispersed even after 30 days and no sedimentation was observed.

An electrode for a lithium ion cell containing graphene powder was prepared according to Example 4 and the discharge capacity was measured, which was measured as 147 mAh / g.

The results are collected in Table 1.

[Example 4]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Preparation of graphene powder: To 200 ml of a dispersion of graphite oxide, 0.5 g of dopamine hydrochloride was added as a dispersant, and 3 g of potassium aditionate was added as a reducing agent. The reduction reaction was carried out with a mechanical stirrer at a room temperature of 23 ° C for 30 minutes as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of graphene powder after reduction was 2.21 x 10 ³ S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measuring the result, the elemental consumption of oxygen to carbon was 0.12 and the elemental consumption of nitrogen to carbon was 0.011. Assuming that all of the nitrogen was derived from dopamine hydrochloride, the weight ratio of dopamine hydrochloride to graphene was calculated to be 15%.

The performance of the dispersion of graphene powder was measured according to Example 3, and as a result it was evenly dispersed even after 30 days and no sedimentation was observed.

An electrode for a lithium ion cell containing a graphene powder was prepared according to Example 4 and the discharge capacity was measured, which was measured to be 151 mAh / g.

The results are collected in Table 1.

[Example 5]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Production method of graphene powder: 0.5 g of catechol was added as a dispersant to 200 ml of a dispersion of graphite oxide, and 3 g of potassium aditionate was added as a reducing agent. The reduction reaction was carried out with a mechanical stirrer at a room temperature of 23 ° C for 30 minutes as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of the graphene powder after reduction was 1.49 x 10 ³ S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measurement, and as a result the elemental consumption of oxygen to carbon was 0.12.

After reduction, the graphene powder was measured by thermal desorption GC-MS. As a result, the weight ratio of catechol in the graphene powder was 14%.

The performance of the dispersion of graphene powder was measured according to Example 3, and as a result it was evenly dispersed even after 30 days and no sedimentation was observed.

An electrode for a lithium ion battery containing graphene powder was prepared according to Example 4 and the discharge capacity was measured, which was measured to be 148 mAh / g.

The results are collected in Table 1.

[Example 6]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Production method of graphene powder: 0.5 g of waveguide was added as a dispersant to 200 ml of a dispersion of graphite oxide, and 3 g of potassium aditionate was added as a reducing agent. The reduction reaction was carried out with a mechanical stirrer at a room temperature of 23 ° C for 30 minutes as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of the graphene powder after reduction was 4.13 x 10 ³ S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measuring the result, the elemental consumption of oxygen to carbon was 0.12 and the elemental consumption of nitrogen to carbon was 0.011. By assuming that all nitrogen was derived from the waveguide, the weight ratio of waveguide to graphene was calculated to be 15%.

The performance of the dispersion of graphene powder was measured according to Example 3, and as a result it was evenly dispersed even after 30 days and no sedimentation was observed.

An electrode for a lithium ion cell containing graphene powder was prepared according to Example 4 for measurement and the discharge capacity was measured, which was measured to be 145 mAh / g.

The results are collected in Table 1.

[Example 7]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Preparation of graphene powder: To 200 ml of a dispersion of graphite oxide, 0.5 g of dopamine hydrochloride was added as a dispersant, and 3 g of sodium aditionate was added as a reducing agent. The reduction reaction temperature was reduced with a mechanical stirrer at 100 ° C for 30 minutes as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of the graphene powder after reduction was 1.01 x 10 ⁴ S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measuring the result, the elemental consumption of oxygen to carbon was 0.11 and the elemental consumption of nitrogen to carbon was 0.014. Assuming that all of the nitrogen was derived from dopamine hydrochloride, the weight ratio of dopamine hydrochloride to graphene was calculated to be 19%.

The performance of the dispersion of graphene powder was measured according to Example 3, and as a result it was evenly dispersed even after 30 days and no sedimentation was observed.

An electrode for a lithium ion cell containing graphene powder was prepared according to Example 4 and the discharge capacity was measured, which was measured to be 142 mAh / g.

The results are collected in Table 1.

[Example 8]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Preparation of graphene powder: 0.5 g of catechol as a dispersant was added to 200 ml of a dispersion of graphite oxide, and 3 g of sodium aditionate was added as a reducing agent. The reduction reaction temperature was reduced with a mechanical stirrer at 100 ° C for 30 minutes as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of the graphene powder after reduction was 6.61 x 10 ³ S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measurement, and as a result the elemental consumption of oxygen to carbon was 0.11.

After reduction, the graphene powder was measured by thermal desorption GC-MS, and as a result, the weight ratio of catechol in the graphene powder was 15%.

The performance of the dispersion of graphene powder was measured according to Example 3, and as a result it was evenly dispersed even after 30 days and no sedimentation was observed.

An electrode for a lithium ion cell containing graphene powder was prepared according to Example 4 for measurement and the discharge capacity was measured, which was measured to be 145 mAh / g.

The results are collected in Table 1.

[Comparative Example 1]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Preparation of graphene powder: 3 g of dopamine hydrochloride was added to 200 ml of a dispersion of graphite oxide and subjected to a reaction for 30 minutes as a reduction reaction temperature at 40 DEG C as a reduction reaction temperature together with a mechanical stirrer. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was measured to 8.70 x 10 ^-4 S / m, and the increase in the electrical conductivity of the powder after reduction was small, which was an insulator.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measurement, and the result showed that the elemental consumption of oxygen to carbon was 0.41 and the elemental consumption of nitrogen to carbon was 0.006. Assuming that all of the nitrogen was derived from dopamine hydrochloride, the weight ratio of dopamine hydrochloride to graphene was calculated to be 6%.

Measurement of the performance of the dispersibility of the powder and measurement of the electrode for a lithium ion battery containing the powder were meaningless.

[Comparative Example 2]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Preparation of graphene powder: 3 g of dopamine hydrochloride was added to 200 ml of a dispersion of graphite oxide and subjected to a reduction reaction with a mechanical stirrer at 100 캜 for 24 hours as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of the graphene powder after reduction was 6.81 x 10 ² S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2, and the result showed that the elemental consumption of oxygen to carbon was 0.23 and the elemental consumption of nitrogen to carbon was 0.013. Assuming that all of the nitrogen was derived from dopamine hydrochloride, the weight ratio of dopamine hydrochloride to graphene was calculated to be 17%.

The performance of the dispersion of graphene powder was measured according to Example 2 and as a result it was evenly dispersed even after 30 days and no sedimentation was observed.

An electrode for a lithium ion battery containing graphene powder was prepared according to Example 3 and the discharge capacity was measured, which was measured to be 129 mAh / g.

The results are collected in Table 1.

[Comparative Example 3]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Preparation of graphene powder: 3 g of catechol was added to 200 ml of a dispersion of graphite oxide and subjected to a reduction reaction with a mechanical stirrer at 40 캜 for 30 minutes as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was measured to 8.70 x 10 ^-4 S / m, and the increase in the electrical conductivity of the powder after reduction was small, which was an insulator.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measurement, and as a result the elemental consumption of oxygen to carbon was 0.42.

After reduction, the graphene powder was measured by thermal desorption GC-MS, and as a result, the weight ratio of catechol in the graphene powder was 13%.

Measurement of the performance of the dispersibility of the powder and measurement of the electrode for a lithium ion battery containing the powder were meaningless.

[Comparative Example 4]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Preparation of graphene powder: 3 g of catechol was added to 200 ml of a dispersion of graphite oxide and subjected to a reduction reaction at a reduction reaction temperature of 100 ° C for 24 hours with a mechanical stirrer. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of the graphene powder after reduction was 5.83 x 10 ² S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measurement, and as a result the elemental consumption of oxygen to carbon was 0.24.

After reduction, the graphene powder was measured by thermal desorption GC-MS. As a result, the weight ratio of catechol in the graphene powder was 14%.

The performance of the dispersion of graphene powder was measured according to Example 2 and as a result it was evenly dispersed even after 30 days and no sedimentation was observed.

An electrode for a lithium ion battery containing graphene powder was prepared according to Example 3 of measurement and the discharge capacity was measured, which was measured to be 121 mAh / g.

The results are collected in Table 1.

[Comparative Example 5]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Production method of graphene powder: 3 g of sodium aditionate was added as a reducing agent to 200 ml of a dispersion of graphite oxide. The reduction reaction temperature was reduced with a mechanical stirrer at 40 ° C for 30 minutes as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of the graphene powder after reduction was 6.90 x 10 ³ S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measurement, and as a result the elemental consumption of oxygen to carbon was 0.090.

The performance of the dispersibility of the graphene powder was measured according to Example 2, and sedimentation was observed after 1 day.

An electrode for a lithium ion cell containing graphene powder was prepared according to Example 3 of measurement and the discharge capacity was measured, which was measured as 113 mAh / g.

The results are collected in Table 1.

[Comparative Example 6]

(1) A graphite oxide dispersion was obtained in the same manner as in Example 1.

(2) Production method of graphene powder: 3 g of hydrazine hydrate was added as a reducing agent to 200 ml of a dispersion of graphite oxide. The reduction reaction temperature was reduced with a mechanical stirrer at 100 ° C for 24 hours as a reduction reaction period. After the resulting graphene dispersion was filtered, the filter cake was redispersed in 100 ml of water and the dispersion was filtered. The process was repeated twice to clean the filter cake. After washing and freeze-drying, a graphene powder was obtained.

(3) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of the graphene powder after reduction was measured to be 5.99 x 10 ³ S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measurement, with the result that the elemental consumption of oxygen to carbon was 0.06.

The performance of the graphene powder dispersion was measured according to Example 2, and as a result, sedimentation was observed after 6 hours.

An electrode for a lithium ion cell containing graphene powder was prepared according to Example 3 of measurement and the discharge capacity was measured, which was measured as 91 mAh / g.

The results are collected in Table 1.

[Comparative Example 7]

(1) The graphite oxide prepared in Synthesis Example 1 was heated to 1000 占 폚 under an argon atmosphere to reduce it to obtain a graphene powder.

(2) Physical properties and performance of graphene

The electrical conductivity of the graphene powder before and after reduction was measured according to Example 1 for measurement. The electrical conductivity of the graphite oxide before reduction was 8.70 x 10 ^-4 S / m and the electrical conductivity of the graphene powder after reduction was 1.59 x 10 ³ S / m.

After reduction, the graphene powder was measured by X-ray photoelectron spectroscopy according to Example 2 for measurement, and as a result the elemental consumption of oxygen to carbon was 0.09.

The performance of the graphene powder dispersion was measured according to Example 2, and as a result, sedimentation was observed after 6 hours.

An electrode for a lithium ion cell containing graphene powder was prepared according to Example 3 of measurement and the discharge capacity was measured, which was measured to be 85 mAh / g.

The results are collected in Table 1.

[Comparative Example 8]

The electrical conductivity of the Graphene Nanoplatelet (Model No. M-5, XG Scientific, Inc., XG Sciences, Inc.) was measured according to Example 1 and the electrical conductivity was found to be 1.43 x 10 ⁴ S / m.

The graphene nano platelet count was measured by X-ray photoelectron spectroscopy according to Example 2, and the result showed that the elemental consumption of oxygen to carbon was 0.04.

The performance of the dispersibility of the graphene powder was measured according to Example 2, and as a result, sedimentation was observed after 2 hours.

An electrode for a lithium ion cell containing graphene powder was prepared according to Example 3 of measurement and the discharge capacity was measured, which was measured as 78 mAh / g.

The results are collected in Table 1.

Claims (10)

Wherein the compound having a catechol group is adsorbed on graphene at a weight ratio of not less than 5% and not more than 50% with respect to graphene, and the original consumption of oxygen to carbon in the graphene powder measured by X-ray photoelectron spectroscopy is 0.06 And not more than 0.20. 2. The method of claim 1, wherein the compound having a catechol group is selected from the group consisting of catechol, dopamine hydrochloride, dopa, noradrenaline, 3,4-dihydroxybenzoic acid, 3,4-dihydroxyphenylacetic acid, And 4-tert-butyl pyrocatechol. The graphene powder according to claim 2, wherein the compound having a catechol group is at least one compound selected from the group consisting of dopamine hydrochloride and wave guide. The graphene powder according to claim 3, wherein the elemental consumption of nitrogen with respect to carbon measured by X-ray photoelectron spectroscopy is not less than 0.005 and not more than 0.02. A lithium ion battery electrode comprising graphene powder, an electrode active material and a binder according to any one of claims 1 to 4. And reducing the graphite oxide in the presence of a compound having a catechol group using a reducing agent having no catechol group to produce the graphene powder according to claim 1. 7. The method of claim 6, wherein the compound having a catechol group is selected from the group consisting of catechol, dopamine hydrochloride, dopa, noradrenaline, 3,4-dihydroxybenzoic acid, 3,4-dihydroxyphenylacetic acid, And 4-tert-butyl pyrocatechol. 5. A method for producing a graphene powder, The process according to claim 6 or 7, wherein the compound having a catechol group is catechol, dopamine hydrochloride or dopa, graphene powder. The process for producing a graphene powder according to any one of claims 6 to 8, wherein the reducing agent is an adrionic acid salt. The process for producing a graphene powder according to claim 9, wherein the adductate is sodium aditionate or potassium adipate.

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